KR102080666B1 - Turbine assemblies for Hydroelectric power devices - Google Patents

Abstract

The purpose of the present invention is to an impeller assembly for a hydroelectric power generation device, which maximizes output efficiency by actively improving the structure of an inlet and the structure of an impeller so that the impeller can receive both the head energy of water and the pressure of the flow thereof to be rotated in a high-efficiency state, providing a strong output. The impeller assembly for a hydroelectric power generation device has the impeller inserted into a body having a cylindrical shape and having an insertion space sealed by a cover member, allows a drive shaft to be supported by a bearing coupled to the cover member, and has the inlet and an outlet formed in the body so that the impeller installed in an inner space is driven. The inlet is formed as an involute curve in the direction of the body from 12 to 4 o′clock to be able to supply a fluid. The outlet is formed in a direction from 6 to 8 o′clock. The impeller has a plurality of fluid baths opened to the inner surface of the body. A closed pressure portion closing the fluid baths is formed between the inlet and the outlet in a direction from 4 to 6 o′clock to increase the moment of rotation of the impeller.

Description

Turbine assemblies for Hydroelectric power devices

The present invention relates to an impeller assembly for a hydroelectric generator, and more particularly, the inlet configuration and the configuration of the impeller so that the free energy of the water and the pressure of the flow rate are simultaneously provided to the impeller to rotate in a high efficiency state to provide a powerful output. To improve the power efficiency to maximize the output efficiency of the impeller assembly for hydropower plant.

In the case of a hydroelectric power generating device capable of providing the potential energy of water with rotational force, it is widely used as a clean energy without pollution, and various power generating devices are provided.

As a representative example, a hydroelectric power generation apparatus of Korean Patent Publication No. 10-0837671 (2008.06.13) is provided, and its configuration is an endless track fixed to a structure installed on water and an endless track. In the hydroelectric generator comprising a connector for connecting another bogie to a bogie and a water stop plate installed in each bogie, and a generator operated by the bogie's driving force, the water stop plate has an inclined surface facing the center portion. It is characterized in that the through hole is installed in the central portion of the holding plate, the holding plate is formed to induce the direction of the water flowing through the extension by forming an extension on one of the inclined surface of the through hole of the central portion.

Another embodiment is the power generation device of the Republic of Korea Patent Publication (B1) 10-0534546 (2005.12.08.) Is composed of a float to be installed on the surface of the water, and a fixing device for suppressing the movement of the float and the generator. The power generation apparatus includes a rail having an endless track, a plurality of pulleys moving along the rails, a connector for connecting the plurality of pulleys to each other, a wing installed at each pulley and absorbing the flow energy of water to move the pulley; The generator is configured to generate electricity by receiving the moving energy of the pulley through a power transmission device, wherein the wing is configured by installing a water plate inside the rim wall, and installing a guide bar in the rim wall. And, the guide plate is installed through the guide bar, it is configured by forming a stopper on both sides of the guide bar.

In the case of the conventional hydroelectric generator configured as described above, it was difficult to derive a strong output because it is installed on the water surface so that the water pressure is concentrated only on the front water plate.

The present inventors have proposed a hydroelectric power generation apparatus of the Republic of Korea Patent Publication (B1) 10-1465724 (2014.12.10.) As a means for solving the above problems.

In the case of the prior art and the supporter in contact with the ground; A supporter standing vertically to be spaced apart from the ground above the supporter; An upper shaft and a lower shaft installed at upper and lower ends of the support so as to be axially supported by bearings; A generator installed on the support such that the upper shaft and the gear box are coupled to each other; An upper sprocket and a lower sprocket installed on the upper shaft and the lower shaft and a chain coupled thereto; A cover member coupled to and formed to have a working space formed in front of the support; An attainer coupled to the chain pin at a predetermined interval to rotate; It is coupled to the attainer and configured to include a water plate passing through the working space in a state spaced apart from the front and the cover member of the support, can provide the weight and free fall of the water at the same time to the generator driving force to maximize power production In addition, it provides a hydroelectric power generation device that can be installed and used in any place, such as a waterway by compactly configured.

However, in the case of the above-described configuration, there was a problem in that the configuration of the device was complicated, which required a lot of manufacturing costs, and a certain quantity had to be continuously provided.

KR 100837671 B1 2008.06.13. KR 100534546 B1 2005.12.08. KR 101465724 B1 2014.12.10.

Accordingly, the present inventors have researched and developed the present invention to solve all the problems in the conventional hydro power generation.

That is, in the present invention, the pressure of the flow rate is provided to the impeller at the same time as the free energy of the flow rate to be introduced, thereby forming an inlet partition in the inlet formed in the main body so as to increase the rotational driving force of the impeller, and the impeller in the blade and the partition wall The fluid tank is partitioned by the fluid tank so that the fluid tank is pressurized by the pressurizing part, and the fluid introduced into the fluid tank is moved to the neighboring fluid tank through the lower spaced part of the blade so that the fluid is vacuumed in the pressurizing chamber to generate a load on the impeller. The present invention has been completed with the technical problem of the present invention in providing an impeller assembly for a hydroelectric generator that maximizes the power generation efficiency by solving the problems.

In the present invention as a means for solving the problem, the first impeller is embedded in the cylindrical body formed in the inner space sealed by the cover member, the drive shaft is supported by the bearing coupled to the cover member, the inlet and outlet to form the body In the impeller assembly for driving the impeller installed in the inner space;

The inlet allows the fluid to be supplied in the involute curve from the 12 o'clock to the 4 o'clock of the main body, and the discharge port is formed at the 8 o'clock in the 6 o'clock direction, and the impeller is opened to the inner surface of the main body. Forming a fluid tank of the inlet and outlet, characterized in that to increase the rotation moment of the impeller by forming a closed pressurization portion in the fluid tank at the 4 o'clock and 6 o'clock direction.

Second, the inlet is formed by at least one inlet partition inward to be able to distribute the fluid evenly to the fluid tank formed in the impeller.

Third, the inlet pressurizing portion is formed at the end of the inlet partition, characterized in that configured to seal a part of the fluid tank formed in the impeller.

Fourth, the impeller is characterized in that the drive shaft and the partition wall is coupled to the lower end, the drive shaft and the blades are spaced apart from each other.

Fifth, the impeller is characterized in that the fluid tank partitioned by a plurality of blades disposed radially to face in the axial direction of the drive shaft so as to be close to the inner surface of the main body, and a plurality of partitions arranged at right angles to the drive shaft. .

Sixth, the blade is characterized in that the top is formed to be curved in the opposite direction of rotation.

Seventh, the front drive shaft of the separation portion is characterized in that the guide piece to the top of the fluid flowing through the separation portion toward the front end of the blade is formed.

Eighth the blades, characterized in that the blade is formed alternately arranged between the drive shaft and the blade formed with a narrow gap, and the blade having a wider gap than the narrow space.

Ninth, the wider spaced front portion of the drive shaft is characterized in that the guide piece to guide the fluid flowing through the spaced portion toward the middle portion of the neighboring blades.

Tenth, the inner surface of the main body and the outer diameter of the impeller is configured to maintain a tolerance of 0.2 ~ 0.5mm is characterized in that to minimize the flow loss without rotating friction of the impeller.

The eleventh drive shaft of the impeller is coupled through a bearing housing coupled to the cover member; The bearing housing forms a seal coupling hole toward the cover member based on the partition wall, forms a bearing coupling hole on the opposite side, and installs a seal and a bearing, respectively, and forms a recess in the lower portion of the seal coupling hole so as to horizontally recess the groove. It characterized in that the discharge hole is formed on the flow path to discharge the fluid leaked through the seal to the outside,

The twelfth pressurization portion is characterized in that it further comprises a pressure control means.

The thirteenth pressure control means includes a pressure control hole formed in the pressure portion of the main body, an adjustment member fitted to the pressure control hole and having one end coupled to the main body and a pin, and installed outside the main body to elevate the control member. It characterized in that it comprises a lifting means.

When using the impeller assembly for a hydro power generator provided by the present invention has the following effects.

-The inlet allows the fluid to be supplied like the involute curve from the 12 o'clock to the 4 o'clock of the main body, and at least one inlet partition is formed inside the inlet to distribute the fluid evenly to the fluid tank formed in the impeller. have.

-The fluid tank partitioned is formed in the impeller, in particular, the separation portion is formed in the lower side of the fluid tank, the fluid moved through the separation function to push the blade can increase the output efficiency.

-Tolerance of 0.2 ~ 0.5mm is maintained between the inner surface of the main body and the tip of the blade constituting the pressure part, so that the flow rate loss can be minimized without the rotation friction of the aberration.

-If it is compactly constructed and installed in small rivers or reservoirs, small hydro power generation is possible.

-Since the pressure adjusting means is provided, the number of the pressurizing portions can be adjusted according to the inflow amount of the fluid flowing through the inlet, thereby eliminating problems such as excessive rotational force generated in the impeller assembly.

1 is a perspective view showing a preferred embodiment of the impeller assembly for a hydro power generator provided in the present invention
2 is an exploded perspective view of FIG.
3 is a side cross-sectional view of FIG.
Figure 4 is a side cross-sectional view of the main body applied to the present invention
Figure 5 is a side cross-sectional view showing another example of the main body applied to the present invention
Figure 6 is a side cross-sectional view showing another example of the main body applied to the present invention
Figure 7 is a perspective view extracting the configuration of the impeller that can be applied to the present invention
8 is a front cross-sectional view of FIG.
9 is a side cross-sectional view of FIG.
Figure 10 is a side cross-sectional view showing another example of the impeller that can be applied to the present invention
Figure 11, Figure 12 is a side cross-sectional view showing another example of the impeller that can be applied to the present invention
Figure 13 is an enlarged cross-sectional view showing the action of the guide piece provided in the one pella applied to the present invention.
Figure 14 is a cross-sectional view showing a coupling state of the drive shaft and the cover member of the impeller applied to the present invention
15 is a side cross-sectional view showing another example of an impeller assembly for a hydro power generator provided by the present invention.
Figure 16 is a cross-sectional view taken from the pressure control means in Figure 15
17 is a side cross-sectional view taken from the pressure control means in FIG.

Best Mode for Carrying Out the Invention Preferred embodiments of the impeller assembly for a hydroelectric generator according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing an embodiment of an impeller assembly for a hydroelectric generator provided in the present invention, Figure 2 is an exploded perspective view of Figure 1, Figure 3 is a side cross-sectional view of Figure 1, Figure 4 Side cross-sectional views of the main body applied to the invention are shown respectively.

The impeller assembly 1 for the hydroelectric generator provided by the present invention allows the pressure (weight) of the flow rate to be provided to the impeller 4 together with the free energy of the flow rate to flow therein so that the driving force of the impeller 4 is rotated. It is intended to be augmented.

The present invention is a main body 2 is provided with a support plate 21, a cover member 3 for sealing the inner space 22 formed in the main body 2, and both ends are supported on the cover member 3 It is made by the combination of the impeller 4 installed in the inner space (22).

The main body 2 is configured in a cylindrical shape, and the cover member 3 is coupled to the open sides so as to be watertight with fixing means such as stay bolts so that the inner space 22 can be sealed.

As shown in FIG. 4, the main body 2 has an inlet 23 and an outlet 24 formed in opposite directions, and are provided in the impeller 4 between the inlet 23 and the outlet 24 in the fluid flow direction. The pressing portion 25 is formed so that the pressing portion 25 sealed by the blade 41 is formed.

The inlet 23 is formed so as to be positioned at the 4 o'clock direction from the 12 o'clock direction, the inlet 23 of the inlet 23 is integrally formed with a flange (23a).

The inlet 23 has a configuration in which a pipe body directed toward the body 2 from the flange 23a side is combined with the body 2 and an involute curve, and at least one inlet partition 23b inside the inlet 23. ) To distribute the fluid evenly to the fluid tank 45 formed in the impeller (4). In the present invention, two inflow partitions 23b are formed in the horizontal direction to show an example in which the fluid can be simultaneously supplied to the plurality of fluid tanks 45 when the impeller 4 rotates in the clockwise direction. Of course, the number can be increased.

In addition, an inlet pressurizing part 23c is further formed at an end of the inlet partition 23b of the inlet port 23 to provide a configuration for sealing a part of the fluid tank 45 formed in the impeller 4. can do. When the inlet pressurizing part 23c is formed as described above, the fluid flowing through the inlet 23 is inflowed into the fluid tank 45 formed in the impeller 4 in a state divided by the inlet partition 23b. When passing through the pressurizing portion (23c) section instantaneous pressing force is generated while providing the functionality to increase the rotational force of the impeller (4), thereby providing an effect of increasing the output efficiency.

In addition, the outlet 24 is formed to be located at the 6 o'clock to 8 o'clock direction, the pressurizing portion 25 is formed to have an angle smaller than the inlet port 23 between the 4 o'clock and 6 o'clock direction and the impeller ( The driving force for rotating 4) is generated.

Figure 6 shows a side cross-sectional view showing another example of the main body applied to the present invention.

In forming the main body as described above, at least one or more inlet partitions 23b are formed inwardly of the inlet 23, but the distances of the fluids introduced by varying the distance from the inlet side of these inlet partitions 23b are different. Induction supply is smooth.

Preferably, the length of the inlet partition wall 23b is increased to the inlet side toward the upper side. This configuration allows the fluid to be supplied first through the lower space when the fluid is introduced into the inlet 23, so that a force for driving the impeller 4 is generated, and provides the functionality to replenish and pressurize the fluid supplied through the upper space. It is to improve the rotational force of the impeller (4).

7 is a perspective view showing the configuration of the impeller that can be applied to the present invention, Figure 8 is a front sectional view of Figure 7, Figure 9 is a side cross-sectional view of Figure 7, 10 to 12 can be applied to the present invention Side cross-sectional views showing different examples of impellers are shown respectively.

As described above, the impeller 4 provided in the present invention allows the drive shaft 4a located at the center thereof to be supported by the bearing on the cover member 3 so as to be free to rotate, and formed on the main body 2. The plurality of fluid tanks 45 are formed to be opened in the circumferential direction so as to be located in the inner space 22.

The impeller 4 includes a plurality of blades 41 and a plurality of partition walls 42 on the drive shaft 4a. The blade 41 is disposed radially so as to be located in the axial direction of the drive shaft 4a so as to be close to the inner surface of the main body 2, and the partition 42 is disposed at the right angle with the drive shaft 4a.

The plurality of partitions 42 have a lower end coupled to the driving shaft 4a in close contact with each other, and the blade 41 has a state in which a spaced portion 43 is formed between the driving shaft 4a and separated from each other. 9)

The spacer 43 may be provided at various heights depending on the diameter of the impeller 4 between the drive shaft 4a.

The spacing part 43 may be configured to have a different height alternately in the circumferential direction as necessary, the blade 41 having a narrow spacing part 43 and a wider spacing than the narrow spacing part. By alternately arranging the blades 41 in which the 43 is formed, the fluid flowing into the fluid tank 45 is discharged to the neighboring fluid tank 45 through the spacer 43.

In the case of the spaced part 43, assuming that the narrow width is 10 mm, the wide width is preferably about 20 mm (see FIG. 10).

In addition, the blade 41 provided in the present invention is formed in a curvature configuration gradually in the opposite direction of rotation (counterclockwise in the coupled state) when viewed in cross-section so that the fluid flowing into the inlet 23 of the main body 2 When it comes in contact with the blade 41 it is to be guided naturally toward the lower space 43.

On the other hand, the guide piece 44 is further formed in the side of the spaced part 43 formed in the lower end of the blade 41 which comprises the impeller 4. The guide piece 44 is a narrow gap of the spaced portion 43 when the fluid descending through the blade 41 is supplied to the neighboring fluid tank 45 through the spaced portion 43 formed at the bottom of the blade 41. The pressure is generated while passing through, and the pressure is directed to the middle portion of the blade 41 located in the rotational direction to provide a function of increasing the rotational force (see FIGS. 11, 12, and 13).

On the other hand, the guide piece 44 may be installed uniformly in front of each spaced portion 43, or alternately installed one by one. In particular, when the spaced portions 43 having different heights are alternately formed, the guide piece 44 is formed only in front of the high spaced portions 43.

In the case of the partition wall 42 in which the driving shaft 4a and the lower end are coupled to each other, the partition wall 42 has a disk shape, and is coupled to both ends of the blade 41 to seal the partition wall at equal intervals between the partition walls 42 disposed on both sides. It is combined to form a fluid tank 45 is opened outward by the blade 41 and the partition 42.

In the present invention, a configuration having four partition walls 42 is proposed, and the number and diameter of the blades 41 and the number of partition walls 42 may be added or subtracted according to the size of the main body 2 or the like.

The outer diameter of the impeller 4 is configured to maintain a tolerance of the inner diameter of the main body 2 and 0.2 ~ 0.5mm to minimize the loss of flow rate without the rotational friction of the impeller (4). Rotation friction occurs when the inner diameter of the main body 2 is smaller than 0.2 to 0.5 mm, and when the tolerance is larger than the inner diameter of the main body 2 and 0.2 to 0.5 mm. The pressing force of 45 decreases, which causes a problem that the rotational force of the impeller 4 falls.

When the impeller 4 is configured as described above, when the fluid supplied through the inlet port 23 is supplied to the narrow narrow fluid tank 45 of the impeller 4, the pressurizing part 25 is closed. When passing through, there is no fluid movement and a load is generated and the impeller stops. When the separation part 43 is formed as described above, a part of the fluid flowing through the inlet port 23 is adjacent to the oil in the rotational direction. Since the movement to the gymnastics 45 can ensure the fluid mobility inside the fluid tank 45 located in the pressurizing portion 25 to prevent the occurrence of the load can ensure a smooth rotational force of the impeller (4). In addition, when the size of the separation unit 43 is different, the fluid movement between the fluid tanks 45 is alternately faster and slower, and mixed with the fluid provided from the inlet port 23 to generate the driving force of the impeller 4 to increase the output. It will work.

That is, the fluid is discharged in the opposite direction of rotation (counterclockwise) through the spacer 23, and the discharged fluid is introduced to the upper end of the blade 41 in the opposite direction of rotation through the guide piece 44. 23 is joined to the fluid flowing through the hitting the rotational direction of the blade 41 of the fluid tank 45 is to generate a rotational force by pushing toward the pressing portion 25 in the rotational direction.

Figure 14 shows a cross-sectional view showing a coupling state of the drive shaft and the cover member of the impeller applied to the present invention.

The drive shaft 4a of the impeller 4 applied to the impeller assembly 1 for the hydroelectric generator is provided in a bearing-supported state on the cover member 3 coupled to both sides of the main body.

As shown, the drive shaft 4a is coupled through a bearing housing 31 coupled to the cover member 3, and prevents fluid from leaking toward the bearing 32, thereby improving the failure of the bearing 32 and the like. One configuration is provided.

That is, in the case of the bearing housing 31, the seal coupling hole 34 is formed toward the cover member 3 based on the partition wall 33, and the bearing coupling hole 35 is formed on the opposite side thereof to form the seal 36 and the seal 36, respectively. The bearing 32 is installed, and the lower portion of the seal coupling hole 34 is horizontally formed to recess the flow path 37, and the discharge hole 38 is formed on the flow path 37 to leak through the seal 36. The fluid can be discharged to the outside, and the fluid blocking ring 39 is coupled to the inside of the seal coupling hole 34 so as to be close to the partition 33 to block the fluid from flowing toward the bearing coupling hole 35. It is provided in one configuration.

This configuration has a configuration in which the fluid is discharged to the outside through the flow path 37 and the discharge hole 28 formed in the seal coupling hole 34 even when the fluid leaks through the seal 36 coupled to the drive shaft 4a. It is possible to eliminate the problem that the bearing 32 is corroded by the fluid.

 15 is a side sectional view showing another example of an impeller assembly for a hydroelectric generator provided in the present invention, FIG. 16 is a plan sectional view taken from the pressure adjusting means in FIG. 15, and FIG. 17 is a pressure in FIG. 15. Figure is a side cross-sectional view of each of the control means.

This is to configure the impeller assembly 1 for the hydroelectric generator as described above, it is to include a pressure control means 5 in the pressing portion 25.

When the pressure adjusting means 5 is installed in the pressurizing part 25 as described above, the pressure or inflow amount of the fluid flowing through the inlet 23 may be arbitrarily adjusted to provide the effect of providing the output uniformly. will be.

Looking at the configuration of the pressure adjusting means (5) provided by the present invention is formed so as to penetrate the pressure adjusting hole (25a) in and out of the pressure portion 25 of the main body 2, the adjustment member (25) 51).

At this time, the adjustment member 51 is coupled to the discharge port 24 side by the main body 2 and the pin 52 so that it can be rotated.

The pressure adjusting hole 25a has a shape expanded by the guide portion 53 coupled to the outside of the main body 2, the adjustment member 51 is operated inside the guide portion 53.

The adjusting member 51, one end of which is coupled to the main body 2 and the pins 52, is rotated about the pins 52 arbitrarily by the elevating means 54.

The elevating means (54) is coupled to the nut (56) to the support (55) that is rolled on the guide portion 53, the nut (56) is the control bolt coupled to the control member (51) so that the front end is rotatable ( 57) to fasten the adjustment member 51 by screwing.

In the case of providing the pressure adjusting means 5 as described above, as shown in FIG. 11, a part of the fluid tank 45 formed in the impeller 4 may be provided to open the pressure part 25.

In other words, when excessive fluid is introduced through the inlet port 23 or is introduced with excessive pressure, an overload may occur in the impeller 4, and in this case, the pressure adjusting means 5 is adjusted to the pressurizing unit 25. By controlling the quantity of the fluid tank 45 is located to reduce the output it is possible to maintain a constant operating efficiency of the impeller assembly (1).

In the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the protection scope of the present invention should not be limited to the described embodiments, but should be defined by equivalents as well as the following claims.

1: Impeller Assembly 2: Main Unit
21: support plate 22: inner space
23: Inlet 23a: Flange
23b: inflow bulkhead 24: outlet
25: Pressure part 25a: Pressure adjusting hole
3: Cover member 31: Bearing housing
32: bearing 33: bulkhead
34: seal coupling hole 35: bearing coupling hole
36: Seal 37: Euro
38: discharge hole 39: blocking ring
4: impeller 4a: drive shaft
41: blade 42: bulkhead
43: Spacer 44: Judo
45: fluid tank 5: pressure regulation means
51: adjustment member 52: pin
53: guide part 54: lifting means
55: support 56: nut
57: adjusting bolt

Claims (13)

The impeller 4 is inserted into the cylindrical body 2 formed with the inner space sealed by the cover member 3, and the drive shaft 4a is supported by a bearing coupled to the cover member 3. 2) in the impeller assembly (1) for the hydroelectric generator to form an inlet (23) and outlet (24) to drive the impeller (4) installed in the inner space (22);
The inlet 23, so that the fluid can be supplied as the involute curve from the 12 o'clock to 4 o'clock of the main body 2, the outlet 24 is formed from the 6 o'clock to 8 o'clock,
The impeller 4 forms a plurality of fluid tanks 45 that are open toward the inner surface of the main body 2,
It is configured to increase the rotation moment of the impeller 4 by forming a pressurized portion 25 in which the fluid tank 45 is closed at 4 o'clock and 6 o'clock between the inlet 23 and the outlet 24. But;
The inlet 23 forms at least one or more inlet partitions 23b inwardly so as to distribute and evenly supply fluid to the fluid tank 45 formed in the impeller 4;
An impeller assembly for a hydroelectric generator, characterized in that the inlet pressurizing portion (23c) is further formed at the end of the inlet partition (23b) to seal a part of the fluid tank (45) formed in the impeller (4).
delete delete The method according to claim 1;
The impeller 4 includes a plurality of blades 41 disposed radially to face the inner surface of the main body 2 in the axial direction of the drive shaft 4a, and a plurality of partition walls disposed at a right angle with the drive shaft 4a. An impeller assembly for a hydro power generator, characterized in that the fluid tank 45 partitioned by the 42 is provided.
The method according to claim 4;
The impeller 4, the drive shaft 4a and the partition wall 42 is coupled to the lower end, the drive shaft 4a and the blade 41 is a hydroelectric generator characterized in that the separation portion 43 is formed to be separated from each other For impeller assembly.
The method according to claim 4;
The blade 41 is an impeller assembly for a hydroelectric generator, characterized in that the top is formed to be curvature in the opposite direction of rotation.
The method according to claim 5;
The blades 41 may include a blade 41 having a narrow spaced portion 43 formed therebetween, and a blade 41 having a wider spaced portion 43 wider than a narrow spaced space. Impeller assembly for a hydroelectric generator, characterized in that alternately arranged.
The method according to claim 5;
Hydroelectric generator, characterized in that formed in the front drive shaft (4a) of the separation portion 43 to guide the fluid introduced through the separation portion 43 toward the distal end of the neighboring blade (41) For impeller assembly.
The method of claim 8;
In the wide spaced portion 43, the front drive shaft (4a) is characterized in that the guide piece 44 to guide the fluid flowing through the spaced portion 43 toward the middle portion of the neighboring blade 41 is formed Impeller assembly for hydro power plant.
The method according to claim 1;
Hydroelectric power generation, characterized in that the inner surface of the main body 2 and the outer diameter of the impeller 4 is configured to maintain a tolerance of 0.2 ~ 0.5mm to minimize the flow rate loss without rotating friction of the impeller (4) Impeller assembly for the device.
The impeller 4 is inserted into the cylindrical body 2 formed with the inner space sealed by the cover member 3, and the drive shaft 4a is supported by a bearing coupled to the cover member 3. 2) in the impeller assembly (1) for the hydroelectric generator to form an inlet (23) and outlet (24) to drive the impeller (4) installed in the inner space (22);
The inlet 23, so that the fluid can be supplied as the involute curve from the 12 o'clock to 4 o'clock of the main body 2, the outlet 24 is formed from the 6 o'clock to 8 o'clock,
The impeller 4 forms a plurality of fluid tanks 45 that are open toward the inner surface of the main body 2,
It is configured to increase the rotation moment of the impeller 4 by forming a pressurized portion 25 in which the fluid tank 45 is closed at 4 o'clock and 6 o'clock between the inlet 23 and the outlet 24. But;
The drive shaft 4a of the impeller 4 is coupled through a bearing housing 31 coupled to the cover member 3;
The bearing housing 31 forms a seal coupling hole 34 toward the cover member 3 based on the partition 33 and forms a bearing coupling hole 35 on the opposite side thereof, respectively, so that the seal 36 and the bearing ( 32), the lower portion of the seal coupling hole (34) is formed to recess the flow path (37) horizontally, the discharge hole (38) is formed on the flow path (37) to leak fluid through the seal (36) An impeller assembly for a hydro power plant, characterized in that it can be discharged to the outside.
The impeller 4 is inserted into the cylindrical body 2 formed with the inner space sealed by the cover member 3, and the drive shaft 4a is supported by a bearing coupled to the cover member 3. 2) in the impeller assembly (1) for the hydroelectric generator to form an inlet (23) and outlet (24) to drive the impeller (4) installed in the inner space (22);
The inlet 23, so that the fluid can be supplied as the involute curve from the 12 o'clock to 4 o'clock of the main body 2, the outlet 24 is formed from the 6 o'clock to 8 o'clock,
The impeller 4 forms a plurality of fluid tanks 45 that are open toward the inner surface of the main body 2,
It is configured to increase the rotation moment of the impeller 4 by forming a pressurized portion 25 in which the fluid tank 45 is closed at 4 o'clock and 6 o'clock between the inlet 23 and the outlet 24. But;
The pressurizing portion 25 is an impeller assembly for a hydro power generator, characterized in that it further comprises a pressure adjusting means (5).
The method of claim 12;
The pressure regulating means (5) is fitted into the pressure adjusting hole (25a) formed in the pressing portion (25) of the main body (2), and the pressure adjusting hole (25a), one end of which is the main body (2) and the pin (52). And an elevating means (54) installed outside the main body (2) to elevate the adjusting member (51).

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